# raspbot_v2 ROS 2 robot platform based on the Yahboom Raspbot V2. Multiple services run as Docker containers, coordinated by Docker Compose. --- ## Sub-projects | Directory | Description | |---|---| | [robot/](robot/README.md) | Differential-drive motor control, pan/tilt camera, and ultrasonic range sensor | | [lidar/](lidar/README.md) | RPLIDAR A1 laser scanner | | [oled/](oled/README.md) | OLED display dashboard | | [wifi/](wifi/README.md) | Wi-Fi hotspot fallback manager | | [camera_publisher/](camera_publisher/README.md) | V4L2 camera → ROS 2 topic publisher | | [webrtc_streamer/](webrtc_streamer/README.md) | WebRTC browser stream server | | [webui/](webui/README.md) | Browser-based robot controller | | [ansible/](ansible/README.md) | Provisioning playbook for the Raspberry Pi | --- ## Setting up the robot ### 1. Flash Raspberry Pi OS Use the [Raspberry Pi Imager](https://www.raspberrypi.com/software/) to write Raspberry Pi OS (64-bit, Lite recommended) to a microSD card. Before writing, open **Advanced options** (⚙) and configure: | Setting | Value | |---|---| | Hostname | `raspbot-v2.local` | | SSH | Enabled | | Username / Password | Your preferred credentials | | Wi-Fi | Your network SSID and password (if not using Ethernet) | Write the image, insert the card, and power on the Pi. Once it is reachable on the network (test with `ping raspbot-v2.local`), proceed to the next step. ### 2. Provision with Ansible The [ansible/](ansible/) directory contains a playbook that handles the remaining setup (enabling SPI, installing Docker). See [ansible/README.md](ansible/README.md) for full instructions. --- ## Building ### Prerequisites - Docker with BuildKit enabled - For cross-compilation from an amd64 host, register QEMU user-space emulation once: ```bash docker run --rm --privileged tonistiigi/binfmt --install arm64 ``` ### Build all images ```bash docker compose build ``` Or build a single service: ```bash docker compose build robot docker compose build lidar ``` --- ## Deploying Pipe images directly to the target over SSH — no intermediate file or registry needed: ```bash docker save raspbot_v2:latest raspbot_v2_lidar:latest \ | ssh @raspbot-v2.local docker load ``` Then copy the compose file and any `.env` to the target: ```bash scp docker-compose.yml @raspbot-v2.local:~/ ``` Replace `` with the username configured in [ansible/inventory.ini](ansible/inventory.ini). --- ## Launching ### Start everything ```bash docker compose up ``` To run in the background: ```bash docker compose up -d docker compose logs -f # follow logs docker compose down # stop and remove containers ``` ### Environment variables Create a `.env` file alongside `docker-compose.yml` to override defaults: ```bash ROS_DOMAIN_ID=0 LIDAR_PORT=/dev/ttyUSB0 LIDAR_FRAME_ID=laser WIFI_SSID=MyNetwork ``` | Variable | Default | Description | |---|---|---| | `ROS_DOMAIN_ID` | `0` | ROS 2 domain — must match on all nodes | | `LIDAR_PORT` | `/dev/ttyUSB0` | Host device node for the RPLIDAR | | `LIDAR_FRAME_ID` | `laser` | `frame_id` in published `LaserScan` messages | | `WIFI_SSID` | _(empty)_ | Target SSID; if unset the Wi-Fi container creates a hotspot immediately | | `HOTSPOT_SSID` | `raspbot-hotspot` | Fallback hotspot SSID | | `HOTSPOT_PASSWORD` | `raspbot1234` | Fallback hotspot passphrase | --- ## Project layout ``` . ├── docker-compose.yml ├── docker-entrypoint.sh ├── robot/ # Motor controller, pan/tilt, ultrasonic ├── lidar/ # RPLIDAR A1 ├── oled/ # OLED display dashboard ├── wifi/ # Wi-Fi hotspot fallback ├── camera_publisher/ # V4L2 camera → ROS 2 topic ├── webrtc_streamer/ # WebRTC browser stream ├── webui/ # Browser-based controller UI └── ansible/ # Raspberry Pi provisioning ```